Fume eliminator and fuel saver for internal-combustion engines



Nov. 11, 1952 G. J. TABER 2,617,398

FUME ELIMINATOR AND FUEL SAVER FOR INTERNAL-COMBUSTION ENGINES Filed March 9, 1950 3 Sheets-Sheet l INVENTOR. @50H65 .l TBER A T'TORNEY NOV. 11, 1952 G, J, TABER 2,617,398

FUME ELIMINATOR AND FUEL SAVER FOR INTERNAL-COMBUSTION ENGINES Filed March 9, 1950 3 Sheets-Sheet 2 59 74 78 56 74 m 55 67 72 7 e e 75 IN VEN TOR. GEO/'PGE 1. TA BER 80 TTORNEY NOV. 11, 1952 G. J. TABER 2,617,398

FUME ELIMINATOR AND FUEL SAVER FOR INTERNAL-COMBUSTION ENGINES Filed Maron 9, 195o s sheets-sheet a GEORGE J. TABER ATTORNEY Patented Nov. 1l, 1952 UNITED STATES PATENT OFFICE FUME ELIM'INATOR AND FUEL SAVER FOR INTERNAL-COMBUSTION ENGINES 20 Claims.

The present invention relates to devices for use on internal combustion engines for the purpose of correcting inherent operational faults. More particularly, the invention relates to devices which are intended for use on automotive vehicles for eliminating fumes, saving fuel and lubricating oil, and improving the service life and performance of the engine.

The internal combustion engine of an automotive vehicle alternately supplies power to drive the vehicle and is driven by the vehicles momentum. The internal combustion engine is designed primarily, however, to produce power, not to absorb it. As is well known, when an internal combustion engine is being driven by the momentum of a vehicle and is operating at greater than idling speed with its throttle closed, as is the case when the vehicle is slowing down or is coasting, fuel is being wasted, lubricating oil is being wasted, and harmful fumes and gases i are generated. The wasted fuel is pulled through the low speed or idling jets of the carburetor; and the lubricating oil provided for the engine is pulled through, or past, the intake manifold or passed into the combustion chambers, for the driven engine acts primarily as a pump, and reduces the pressure within the intake manifold and combustion chambers excessively. Furthermore, as the lubricating oil is pumped past the valve guides and pistons, air is also displaced,

and the pressure within the oil sump area is also reduced. The reduction of pressure in the oil sump area causes moisture-laden atmosphere air and abrasive dusts to be drawn into the oil sump by means of the normally supplied sump vents. The oil sump is chilled by the intaken air and condensate results; the admitted abrasives further contaminate the oil. Thus it too becomes sludged, and accelerates engine wear. The power absorption periods preclude the combustion of the wasted fuel and oil. The improper combustion of the fuel results not only in the formation of gases, which are not only injurious to health and obnoxious to the sense of smell, but, if sulfur is present in the fuel or oil, are harmful to the engine itself. The coinbustion failure causes an irregular exhaust pattern 0f the engine as the vehicle speed is reduced, and is itself the result of the starve-:l engine displacement. The wasted fuel and oil are, moreover, mixed within the engine and partially distilled by local hot spots within the engine so that some gases and some solids are formed which are passed or circulated through the engine and which coat all the exposed parts.

such as valve stems, cylinder walls, combustion chamber, intake and exhaust manifolds, exhaust pipe and mufer, with an aciduous, corrosive coating, causing sticking valves and piston rings, carbon formation, fouled spark plugs, and rusted and plugged mufllers. The mixture is finally passed out into the city streets, and is a cause of resentment to pedestrians, and to autoists following a bus, and is detrimental to public health and to good public relations.

In order to eliminate the fumes and to save gas, various devices have been proposed in the past incorporating an automatically operating valve on the intake manifold of an internal combustion engine which will open automatically when the accelerator, and hence the carburetor throttle, is moved toward idling position, and the vehicle is driving the engine at a speed greater than that corresponding to the position of the throttle. With such an arrangement the carburetor throttle may be by-passed when the engine is being driven by the momentum of the vehicle, and fresh air only may be drawn into the combustion chambers of the engine through the open valve, thereby eliminating waste of fuel and formation of noxious gases and fumes.

Such systems as have heretobefore been devised for this purpose, however, are either too sensitive in operation, causing a full power on, full power oif operating cycle, which interferes with smooth operation of the vehicle, or they do not permit the broad operating range which is required for successful operation, or they are unable to supply free atmospheric air in quantities which will relieve the engines displacement or provide proper scavenging air velocities, or are costly in construction not easily adapted to general use, or cause an undesirable vehicle acceleration when they become operative.

One object of the present invention is to provide an improved device of this type which will permit unrestricted passage of air into the combustion chambers of an internal combustion engine, whenever the engine is being driven by the momentum of the vehicle at greater than idling speed, and which will operate to completely destroy under these conditions the intake manifold vacuum, prevent flow of fuel to the engine, and convert the engine into a compressor. As long as the engine is driven by vehicle momentum, then, air will be compressed and exhausted, and abrasive dusts and moisture-laden air will be prevented from being drawn into the crankcase or oil sump to contaminate the lubricating oil.

Another' object of the invention is to provide apparatus of the character described which is primarily controlled by and is caused to become operable under the influence of the partial vacuum existing Within the intake manifold of a decelerating and power-absorbing internal combustion engine.

Another object ofv this invention is to provide apparatus of the character described which employs an electro-vacuum assist mechanism which coacts with electro-magnetically operated parts to assist and cause the opening of a valve through which the partial vacuum created in the intake manifold may influence the action of the valve that by-passes air around the carburetor throttle.

A further object of this invention is to provide apparatus of the character described which is maintained in an operable, or active air bypassing, state by the combined influences of the partial vacuum within the intake manifold, the prime source of electrical energy for the engine,` and the partial vacuum induced by in-rush of air by-passing the carburetor throttle.

A further object of this invention is to provide apparatus of the character described which is rendered active, so that air may be by-passed into the engine, by the combination of an electrically induced magnetic eld, an elecro-magnetically responsive valve mechanism, a movable member which reacts to changing pressures, or partial vacuum and which controls another movable member that reacts to conditions of changing pressures and that is movable to bypass the carburetor throttle and pass air into the intake manifold of the engine. p

A further object of this invention is to provide apparatus of the character described which will supply free atmospheric air directly to the intake manifold of an internal combustion engine in by-pass of the engines carburetor throttle and in such quantities, and at such velocities that the in-rushing air can scavenge any accumulation of waste fuel or lubricating oil within the intake manifold or the combustion chambers of the engine, and can cause the accumulation to be cleared out of the engine and the exhaust system. thereby preventing formation of harmful fumes, gases and solids.

Another object of the invention is to provide apparatus of the character described which will operate without causing an undesired acceleration of the vehicle when the engine throttle is purposely closed to reduce vehicle speed.

Another object of the invention is to provide apparatus of the character described which can easily be installed.

Still another object of the invention is to provide apparatus of the character described which may easily be adjusted or calibrated to control the timing and latitude of its operation, and to regulate both the time when the apparatus becomes operative, and the time when it becomes inoperative so as to prevent stalling of the vehicle.

Another object of the invention is to provide apparatus of the character described which is automatically rendered inoperable when the speed of the engine is decreased to a certain predetermined limit.

Another object of the invention is to provide apparatus of the character described which is lpartially controlled, at least, through the medium of an electro-mechanical switch that is responsive to changing rate of electric impulse transmis-k sion, which is synchronous with the engine speed and which may be actuated through the primary circuit of the electrical ignition system of the vehicle.

Another obj ect of the invention is to provide apparatus of the character described which is operative only when the engine is caused to absorb power and consequently which will have no effect on-the engine when there is a demand for power. A further obj ect of the invention is to provide apparatus of the character described which is so constructed that it will not function on a cold engine and will not prolong the engine warm up time.

Still further objects of the invention are to provide apparatus of the character described which will be quiet in operation, simple in construction, and extremely eicient.

vOther objects of the invention will be apparent hereinafter from the specification and from the recital of the appended claims.

In the drawings:

Fig. 1 is a perspective view of an internal com bustion engine showing a device constructed according to one embodiment of this invention installed thereon;

Fig. 2 is a fragmentary view on an enlarged scale showing, partly in section and partly in elevation, a portion of the intake manifold of the engine, a portion of the carburetor, the valve unit and air lllter forming a part of the device of the present invention, and the support or adapter by means of which this unit is mounted between the intake manifold and the carburetor;

Fig. 3 is a sectional view of the detent switch of the mechanism and of the parts which are associated with this switch and which operate the same;

Fig. 4 is a sectional view of the vacuum switch of the mechanism;

Fig. 5 is a view showing one of the parts of this vacuum switch;

Fig. 6 is a vertical sectional view on an enlarged scale showing the valve mechanism and air filter of the present apparatus and the mounting of these parts, the several parts being shown in the positions they occupy when the engine is supplying power to the vehicle;

Fig. 7 is a fragmentary vertical sectional View showing some of the parts of Fig. 6 in the positions which they occupy at the first stage of operation of the valve mechanism after the solenoid is energized;

Fig. 8 is a further vertical sectional View showing the parts at the final stage in the operation of the valve mechanism, the section being taken at right angles to the section of Figs. 6 and '7;

Fig. 9 is a plan view showing the `electrical governor of the apparatus;

Fig. l0 is an elevation of this governor; and

Fig. 11 is an electrical diagram showing one way in which the parts of the apparatus may be wired to perform their function.

Referring now to the drawings by numerals of reference, 20 denotes an internal combustion engine of conventional design, and 2| are the intake manifolds of this engine. 23 denotes a conventional carburetor, and 24 denotes a conventional air inlet strainer associated with this carburetor. 25 (Fig. 2) denotes the butterfly valve of the carburetor. This is adapted tobe operated in conventional fashion from the accelerator pedal 2S of the vehicle through the leverage 21, link 28, lever arm 29, shaft 30, lever arm 29', link 3l, and bell-crank lever 32, the last-named being connected to the accelerator pedal 26. v

The mechanism for operating the butterfly valve is of conventional design except that the rod 28 is made in parts 28 and 28" (Fig. 3) and has interposed between the two parts a detent switch. This detent switch comprises a cylindrical housing which has end walls 36 and 31. The part 28 of rod 28 threads into end wall Mounted in the other end wall 31 of this housing is a sleeve 38 into which the other section 28" of the rod 23 threads. The sleeve 38 is slidably reciprocable in the end wall 31 and is guided thereby. Secured at diametrically opposite points in the cylindrical housing 35 are the two terminal posts 39 to which are fastened the terminal contacts 48 and 4|. Terminal screws 42 thread into the posts 39. The terminals 40 and 4| are adapted to be bridged by a plate 44 which is secured by means of an insulator sleeve 45 on the tubular member 38.

The detent switch is a normally open switch, being held open by a coil spring 41 which is interposed between the end wall 35 of the housing and a washer 48 that is secured to the head of the sleeve 38. This switch may be supplied in either pull or push types. The throttle-return spring pressure should cause this switch to close its circuit when the throttle is at idling position. In other words, the detent switch is adapted to close when the accelerator pedal is released and reaches idling position.

Mounted on the intake manifold or any suitable part of the engine is an initiator switch 50 (Figs. l and 4). This switch comprises a cupped housing 5| which has a tubular extension 52 at one end that is adapted to be threaded into the intake manifold of the engine. Mounted in the housing 5| is a disc diaphragm member 5B which is .secured between a cup-shaped washer 54 and a clamping disc 51. The clamping disc 51 seats, in the shown position of the diaphragm, against the base portion of a cup-shaped member 58. The diaphragm is held at its outer edge between the member 58 and the left hand end wall of housing 5|. The cup-shaped member 58 is held between diaphragm 56 and a rigid plate 59 made of a suitable insulating material that closes the open end of the housing 5|. The end plate 59 is secured in position by the flange portion 60 of the housing. The washer 54, diaphragm 56, and clamping disc 51 are secured to the head of a bolt or rod '62 which is slidably mounted in a bushing 63 that is secured centrally in the end plate 59. The cup-shaped member 58 has a central hole in it through which the bolt 62 passes. Threaded onto the outer end of the bolt 62 is a cup-shaped cap 64; and interposed between this cap and the end-plate 59 is a coil spring 65.

Mounted in the end plate 59 are two electrical terminal posts 61 and G8. Riveted to a bracket .'0 that is secured to the post 61 is a exible arm 1| which is shaped as shown in Fig. 5. The bolt E2 passes through the slot 18 in this arm. This arm is formed with furcations 12 that are riveted to the bracket 10; and between these furcations it is formed with an intermediate tab 13 which is reversely bent and which has a button 14 Secured to it. At its free end, the arm 1| carries a contact member 15. The button 14 is adapted to contact with the back of the clamping disc 51.

The coil spring 65 serves normally to hold the parts in the positions shown in Fig. 4. When the parts are in these positions, the plate 51, through its Contact with button 14, lexes the arm 1| and holds the contact 15 in engagement with a stop 16 that is secured to the post 68. When the engine is being driven by the momentum of the vehicle. however, the suction generated pulls the diaphragm 56 to the left in Fig. 4 against the resistance of spring 65. The arm 1| is then left free to iiex to its normal position bringing the contact 15 into engagement with the plate 11 that is secured to the post E8. The arm 1| which is an electrical conductor, thus bridges terminals 61 and 68 and makes an electric circuit between these posts or terminals 68 and B1.

The initiator switch is, therefore, a normally open switch which responds to change of intake manifold Vacuum. Adjustment of this switch is achieved simply by turning the spring loaded cap 64. By adjusting this cap, the time when the valve mechanism of the present invention becomes operative may be controlled.

When the apparatus of the present invention is used, an adapter is secured between the intake manifold 2| and the carburetor 23. This adapter may be in the form of a hollow casing (Fig. 2) which is secured in place by the bolts 82 that also serve to secure the carburetor in position.

The casting 80 may be shaped, as shown, to extend to one side of the carburetor. Mounted upon its upper face at the extremity thereof is a combined lter and valve unit enclosed in a housing 85. This housing is secured to the casting by screws 86. The outside wall of this housing is provided with a plurality of large size vent openings 81 through which air may be admitted. Mounted between the outside wall of the housing and an inner wall 89 is a cylindrical air filter SG (Fig. 6)

Secured in the top of the housing 85 is the upper portion 9| (Fig. 6) of the solenoid outer magnetic member constituting one pole of the solenoid. This is secured to housing 85 by pole piece 92 which also serves to secure sleeve 93 to the housing. This sleeve is formed at its lower end with a cup-shaped portion 94 of enlarged diameter, as shown in Figs. 6, '7 and 8. Surrounding lthe smaller diameter portion of the sleeve and interposed between the member 9| and a magnetic member 9G, which constitutes the opposite pole of the solenoid, is a solenoid coil 95. This coil is insulated from sleeve 93 by suitable insulation 91. The two members 9| and 96 have non-magnetic spacers 99 between them and are secured together by non-magnetic rivets 99.

Mounted to reciprocate the sleeve 93 is the armature of the solenoid. The armature 98 is normally pressed downwardly by a coil spring |89 which is interposed between the head of the bolt 92 and the armature. The bolt 92 has a conical head |91 and the armature has a conical recess |52 to receive this head when the armature is moved vertically upwardly upon energization of the solenoid. The armature has a conical lower end |94 which acts as a valve and which seats in conically shaped seat |95 (Fig. 7) provided in the upper end of a tube |96 which is welded or otherwise secured to a cup-shaped servo-piston or valve |91.

This piston or valve is adapted to reciprocate in the cup-shaped portion 94 of the sleeve 93. When it is in its lower position it is adapted to rest upon the upper end of a Venturi-tube H0. This tube is outwardly crimped midway of its length and rests with air-tightness in an opening provided in the loza-fer end wall H2 of a hollow piston-valve i iii. This piston-valve is adapted to slide in the inner wall 59 or" the housing 85 and is adapted to be guided therein. in its lower position it seats on adapter and closes the port H6 in the upper face of this adapter. It has an enlarged opening H in its upper end wall so that it may be moved upwardly and pass over the solenoid coil 95.

When the solenoid 95 is energized, the armature 90 will be pulled upwardly against the resistance of the spring |00. When the solenoid plunger valve 98 is lifted, the tube |06 is opened. 'I'his unbalances the pressure on the servo-piston or valve |01, leaving it with a larger area exposed to air pressure at the bottom than at the top. Hence, as the upper chamber |09 (Fig. 7) ofthe servo-piston |01 is evacuated, the servopiston'will rise until it enters the magnetic field of the solenoid. Thereafter, as long as the solenoid is energized, it will be held magnetically in its upper position. The moment that the servo-piston leaves its seat on the Venturi-tube I l0, the Venturi-tube is opened and consequently the upper chamber H3 in which the main piston valve |4 is adapted to slide is evacuated through the opening H5 in the main piston valve H4, causing `this valve to rise since it is also unbalanced. This valve or piston is lifted until it is magnetically locked in its upper position by completing the magnetic path of the field surrounding the solenoid. This is done by contact of valve H4 around its periphery with laterally extended portions of members 9| and 96 whose lower faces lie in the same horizontal plane, see Fig. 8. Thereafter the piston valve I I4 is held in its upper position until the governor, now to be described, breaks the solenoid circuit of its own accord, or until the impulse circuit to the governor is broken by the action of the detent switch when there is a demand for power and the accelerator throttle is advanced. When the valve ||4 is opened, air can flow through the vents 81 in housing 85, filter 90, port H6, and adapter 80 into the intake manifold of the engine. Thus clean air will be sucked into the engine on its suction strokes during the time the engine is being driven by the momentum of the vehicle. The adapter 80 has a port ||1 (Fig. 2) communicating with the intake manifold. It has also another port H8 with which the carburetor registers so that the carburetor may perform its function when the engine is driving the vehicle and valve I4 is closed.

The governor I I9 (Figs. 1, 9 and 10) may be mounted at any suitable point on the vehicle as for instance the dashboard, being preferably secured adjacent to the voltage regulator. It may comprise two electromagnets and |2| of conventional construction and two capacitors |22 and |23 also of conventional construction. These may all be mounted upon a common plate |24 which may be secured to the dishboard of Vthis vehicle by screws passed through holes |26 and which, in turn, may be secured in any suitable fashion to a base |25 that is fastened to the back of the dashboard or other part of the vehicle by screws which are passed through holes |26 in the ears |21. Holes |28 are for attaching a suitable cover.

Secured to pivoted plates |30 and |3| above the two electromagnets |20 and |2| are the pairs of switch arms |32 and |33, and |34 and |35, respectively. The switch arms |32 and |33 are adapted to be held in upper position by a coil spring |31 which is secured to the base plate |24 at one end and which is secured at its opposite end to the end of an arm |38 that is fastened by a. bolt |39 to the plate |30. Similarly, switch arms |34 and |35 are normally held open by a coil spring I 4| which is secured at one end to the base |24 and at its opposite end to the tail of an arm |42 that is fastened to plate |3|. A stop |43 may be provided to limit upward movement of plate |3I. Switch arms |32, |33, |34 and |35 are adapted to make contact with terminals carried by plates |44, |45, |46 and |41, respectively. The structure is conventional and need not further be described.

, One way in which the apparatus may be wired electrically to perform its function is illustrated diagrammatically in Fig. 11. Here |50 denotes the battery of the automotive vehicle. |5| denotes the conventional ignition switch of the vehicle which is manually operated. |52 denotes the conventional make and break switch of the ignition system whose position is controlled in conventional manner by the conventional rotating cam |53. To start the car the switch |5| must be closed; and all the while the engine is running the cam |53 revolves to make and break contact alternately between the switch |52 and the line |54. 1

The ignition system, as such, forms no part of the present invention. A typical wiring diagram of this system is included in Fig. 11, however, since the make and break switch |52 partly controls operation of the apparatus of the present invention as will hereinafter be described. Closing of the switch |5| makes a circuit to the primary coil |56 ofthe ignition system from the battery |50 through line |55, switch |5I, coil |56, line |51, switch |52, when cam |53 has been rotated to a position to permit switch |52 to close, line |54, and the ground, which is denoted diagrammatically by the line |5I. Capacitor |62, which is connected with line |51 and the ground |6|. serves in the usual fashion. The secondary coil nf the ignition system is denoted at |66.

When the accelerator pedal 26 is released as above described, the detent lswitch 44 (Figs. 3 and ll) is closed. As soon as the vacuum has been built up to the desired degree after the momentum of ythe vehicle starts to drive the engine, the vacuum-operated switch 1| (Figs. 4 and l1) is closed by suction upon the diaphragm 56. Upon opening of breaker arm |52 in the operation of the ignition, a circuit is made from the battery |50 through the line |55, the closed ignition switch |5I, the primary coil |56 of the ignition, lines |51 and |56, the now-closed vacuum switch 1I, the line |59, the coil of the relay |20, and the lines |60 and |6| back to the battery.

This energizes the relay |20 and causes it to close the switch arms |32 and |33 (Figs. 9, 10 and 11). The closing of these switch arms makes a circuit to the coil of relay |2I, this circuit being from the battery |50 through line |55, the coil |2I, the line |63, the line |64, the nowclosed switch arm |33, the line |65 and ground |6| back to the battery. The energization of the relay |2| causes the switch arms |34 and |35 to be closed. This energizes solenoid 95, a circuit being made from the battery through the -line |55, line |61, switch arm |34, line |68, solenoid 95, and ground |6| back to the battery. The solenoid is thus energized to initiate the openingof the valves |01 and H (Figs. 6, 7 and 8.) which-permit air to flow into the intake manifold. The closing of the switch arm |35 makes a circuit to the resistor |69 which suppresses any spark because it allows suicient current to flow through the primary coil |56 9 without the flow of current through the primary coil being interrupted by the opening and closing of breaker point |52. This eliminates cutting of the electrical lines of force which are necessary to produce a high voltage spark from secondary winding |55 of the ignition coil. This prevents an unwanted acceleration of the engineA which would result if an accumulation of raw fuel in the intake manifold were carried into the combustion chambers by in-rush cf by-` passing air on opening of the valve H4, and if this fuel were ignited.

The vacuum switch 1| opens upon opening of valve l!! because the pressure of air owing through port ||5 and adapter 80 into the intake manifold destroys the vacuum that has previously caused switch arm 1| (Figa) to be shifted, and the switch arm 1| is returned to the position shown in Fig. 4 by action of coil spring G5. is in operation, the circuit to the relay coil must be maintained through the closed detent switch lla, the line |10, the now closed switch arm |32, the line |1|, the coil |20, the line |60,

ground 55|.

The circuit to coil |20 may be broken by stepping on accelerator pedal (Fig. l). This opens detent switch 44. The detent switch serves only the purpose of breaking the circuit whenY there is demand for power from the engine. It cannot in any way initiate any circuit. Y

The circuit to coil |20 is also broken when the vehicle slows down to a predetermined point which is adjustable and which is above the stalln ing point of the engine. As the car slows down, the speed of rotation of the cam |53 decreases. rThis means that the frequency of the impulses resulting from the opening and closing switch |52 decreases. Each time that the switch |52 opens, the circuit to the coil |20 will be completed; and when switch |52 is closed the circuit to coil |2t will be broken. If the cam |53 is rotating at high enough speed, the electrical reluctance will keep the switches |32 and |33 closedA to maintain the circuit to the coils |20 and |2|.

When the speed of rotation of cam |53 has slowed down to a predetermined point, however, the frequency of the make and break of the switch arm |52 will have decreased so greatly that the electrical reluctance will not be able toA maintain the circuit, after closing of arm |52, and the coils |20 and |2| will be deenergized. The cycle of operation will be, therefore, completed.

While the operation of the mechanism will be understood from the preceding description, it-

may be briefly summed up here. When the accelerator pedal 26 is released, the detent switch 44- Inay close. The initiator switch 1| will then respond to a change in the intake manifold vacuum and cause the governor ||9 to become electrically energized when the intake manifoldvacuum rises in response to a power absorptionv period. The moment the relay |20 of the governor is energized and the switch arms |32 andv |33 are closed, the secondary relay coil |2| of the governor will be energized and the switch arms |34 and |35 will be closed. This completes the circuit to the solenoid 95. The solenoid 95 is thus energized and lifts the core-piece 90. This permits the chamber |09 (Figs. 6 and '1) of the sleeve S3 to be evacuated by the pull of vacuumin the engine through the intake manifold and the adapter 80. Air pressure on the lowerside of the servo-piston |01 will then lift this piston into the magnetic eld of the solenoid and this Thereafter, as long as the apparatusY piston will be locked in its upper position by magnetic attraction. The moment the servo# piston leaves its seat on the Venturi tube |0, the chamber in the hollow piston-valve |14 and the chamber ||3 between the upper end of this valve and the casing are evacuated through the adapter 80 and the intake manifold. The air pressure on the under side of the valve |14 then causes the valve to rise until it enters the magnetic field of the solenoid. Thereafter it is held in operative position as long as the apparatus is in operation. The fresh air is therefore sucked by the engine directly through the intake openings 01 in the housing 35 and through the filter into the engine. This preventsl formation of an unexploded explosive mixture in the engine, and prevents formation of fumes and all of the deleterious effects that ordinarily result when the engine is being driven.

To avoid. vibration or chatter and switch breaker-point arcing, as each impulse is transfmitled through the relay |2| to solenoid 95, capacitors |22 and |23 are provided.

The piston valve is held up until the governor breaks the solenoid circuit of its own accord or theimpulse circuit of the governor ||9 is broken by the action of the detent switch 44 when there is a demand for power and the throttle is advanced by stepping on accelerator pedal 20.

At the end of the cycle of operation of the present device, the solenoid circuit is brokennand the plunger Valve 98 drops to close the port of the servo-piston |01 which in turn drops and 'closes the port of the main piston valve |I4 which is pulled shut by the resulting drag of the flowing air currents and by its own weight. Thus, the return speed of the main piston valve ||4v is governed by the force of spring |00 and the mass of the plunger valve 98, and the mass and clear` ances of the servo-piston |01 and the main pis` ton f |4. The venturi ||0 assists in the evacuat ing when the apparatus begins to operate and it also assists gravity in closing the valve ||4' at the end of thecycle of operation.

By adjusting the switch arms |32 and |33 of the governor, the point where the coils |20 and |2| are cut out can be adjusted. The governor is a conventional type relay and this adjustment canvbe made in conventional manner by varying pull-out pressure and magnetic air gaps. This point is preferably, as already stated, above the stalling point of the engine so as to insure against stalling the engine during operation Vof the device of the present invention.

To obtain the maximum economy in vehicle operation, the device should be adjusted toj in# sure'the quickest cut-in time and the latest dropout time. Cut-in time is controlled by the initiator switch 1| and drop-out time is controlled' by' the governor |19. Y

The properly adjusted apparatus' will not op"-V erate if the engine is cold and partially choked. A partially-applied chokeV opens the carburetor slightly Vand theV enginewill not achieve` its nor-y mal vacuum.v Thus the initiator switch T,| will not be' closed toyclose the circuit'to the apparatusV of this invention.

The entire apparatus isof. course,` inactive duringpower` production. The apparatus is not energizedor made active until the intake mani-L fold pressure is suliciently great' to" close the vacuum-operated and responsive switch 1|.

'.IfheV control of the device of the presenty invenuqn is Kthrough magneuer'eiays liza and m which are acted on by the electrical impulses causes by the opening and closing of the ignition breaker points |52. These impulses increase in frequency or decrease in frequency in direct relation to the engine speed. Hence, the dropout or anti-stall point of the apparatus can be controlled directly by the impulses generated by the ignition system. Since the vacuum or initiator switch ll provides the means for determining when the apparatus will operate, the, device will only cut in when the manifold pressure reaches the pre-determined level. Hence, the old fault of sensitive throttle control is com-.- pletely removed.

Ignition damping through resistance |69 is a feature of the apparatus of the invention. Its purpose is to prevent unwanted acceleration when the valve becomes operative.

The apparatus of the present invention is relatively insensitive and has a wide latitude. It is relatively cheap. The parts from which it may be made are light and it can function under high intake manifold conditions. It is quiet and is easily adjustable.

While the invention has been described in connection with apparatus for use on an automotive engine, it is not limited to such use. It may be employed on any electrically ignited internal combustion engine including those of the semidiesel type and including stationary engines, the detent switch in the last named case being operated upon movement of the control lever toward idling position.

In general, it may be said, then, that while the invention has been described in connection with a specific embodiment thereof, it is capable o-f further modification, and this application is intended to cover any variations, uses, or adapta tions of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice in the art to which the invention pertains and as may be applied to the essential features hereinbefore set forth and as fall within the scope of the invention or the limits of the appended claims.

Having thus described my invention, what I claim is:

1. The combination with the intake manifold of an internal combustion engine, an accelerator for the engine, an air-intake conduit for supply ing air directly to the manifold, and a valve in said conduit, which when closed shuts olf the di-A rect air supply, of means for controlling the position of said valve, and means connecting the accelerator with said means whereby upon movement of the accelerator toward idling speed and decrease of the engine speed to a, predetermined point said control means is actuated to valveopening position, and separate means operated upon reduction of the engine speed to a further point to actuate said means to Valve-closing position.

2. The combination with the intake manifold of an internal combustion engine, an accelerator for the engine, an air-intake conduit for supplying air directly tothe manifold, a valve in said conduit which when closed shuts off the air supply, and an ignition system for the engine, of means for controlling the position of said valve, and means connecting the accelerator with said means whereby uponmovement of the accelerator toward idling speed and decrease of the engine speed to a predetermined point said control means is actuated to valve-opening position, and

means connecting the ignition system to said 12 control means whereby upon reduction of the engine speed to a further point, said Valve closes.

3. The combination with the intake manifold of an internal combustion engine, an accelerator for the engine, an air-intake conduit for supplying air directly to the manifold, a valve in said conduit which when closed shuts off the direct air supply, said Valve being movable to open position when there is a differential in pressure on its outer and inside surfaces, and an ignition system for the engine, of electrically operated means operable to expose the one surface of said valve to the vacuum generated by operation of the engine and the other surface of the valve to atmospheric pressure when the accelerator is moved toward idling speed and the engine speed has decreased to a predetermined point, said electrically operated means being so electrically connected to the ignition system that when the frequency of the impulses produced by the ignition system falls to a predetermined value said electrically operated means will be rendered inoperative whereupon said valve will close.

Li. The combination with the intake manifold of an internal combustion engine, an air-intake conduit for supplying air directly to the manifold, and a valve in said conduit which when closed shuts olf the direct air supply to the manifold, said valve being movable to open position when thereis. a differential in pressure on its outer and inner surfaces, said valve having a port in it through which one surface of the valve may be exposed to vacuum generated by the engine, an auxiliary valve closing said port and `means operable when the engine speed falls to a predetermined point to open said auxiliary valve.

5. The combination with the intake manifold of an internal combustion engine, an air-intake conduit for supplying air directly to the manifold, and a valve in said conduit which when closed shuts off the direct air supply to the manifold, said valve being movable to open position when there is a. differential in pressure on its outer and inner surfaces, said valve having a port in it through which one surface of the valve may be exposed to vacuum generated by the engine, an auxiliary valve closing said port and rneans operable when the engine speed falls to a predetermined point to open said auxiliary valve and separate means operated when the speed of the engine falls to a still lower predetermined point to close said auxiliary valve.

6. The combination with the intake manifold of an internal combustion engine, an air-intake conduit for supplying air directly to the manifold and a valve in said conduit which when closed shuts off the direct air supply to the manifold, said valve being movable to open position when there is a differential in pressure on its outer and inner surfaces, said valve having a port in it through which one surface of the valve may be exposed to the vacuum generated by the engine, an auxiliary valve closing said port, said auxiliary valve being also normally closed and movable to open position only when there is a differential in pressure on its outer and inner surfaces, said auxiliaryvalve also having a port in it through which one surface of the auxiliary valve may be exposed to the vacuum generated by the engine, a third valve normally closing the port in the auxiliary Valve, and means operable when the engine speed falls to a predetermined point to open said third valve.

7. The combination with the intake manifold of Aan internal combustion engine, an air-intake conduit for supplying air directly to the manifold and a valve in said conduit which when closed shuts off the direct air supply to the manifold, said valve being movable to open position when there is a differential in pressure on its outer and inner surfaces, said valve having a port in it through which one surface of the valve may be exposed to the vacuum generated by the engine, an auxiliary valve closing said port, said auxiliary valve being also normally closed and movable to open position only when there is a differential in pressure on its outer and inner surfaces, said auxiliary valve also having a port in it through which one surface of the auxiliary valve may be exposed to the vacuum generated by the engine, a third valve normally closing the port in the auxiliary valve, and means operable when the engine speed falls to a predetermined point to open said third valve and separate means operated when the speed of the engine falls to a still lower predetermined point to close said third valve.

8. The combination with the intake manifold of an internal combustion engine, an air-intake conduit for supplying air directly to the manifold, a hollow piston-valve in said conduit which when closed shuts off direct air supply to the manifold, a chamber in which said valve is reciprocable, said valve being mounted to project far enough from said chamber in its closed position so that its outer surface is exposed to atmospheric pressure, said valve having a port therein, an auxiliary valve normally closing said port, and means operable when the speed of the engine falls to a predetermined point to open said auxiliary valve to permit the engine to evacuate said first-named valve and the chamber in which it moves whereby to open said first-named valve by the differential in pressure on its opposite sides.

9. The combination with the intake manifold of an internal combustion engine, an accelerator for the engine, an air-intake conduit for supplying air directly to the manifold, a hollow piston valve in said conduit which when closed shuts off direct air supply to the manifold, a chamber in which said valve is reciprocable, said valve being mounted to project far enough from said chamber in its closed position so that its outer surface is exposed to atmospheric pressure, said valve having a port therein, an auxiliary hollow piston valve normally closing said port, a chamber in which the auxiliary valve reciprocates, said auxiliary valve having a port therein, a valve for closing the last-named port, a solenoid for opening said valve, and means operable when the speed of the engine falls to a predetermined point upon movement of the accelerator toward idling speed to energize said solenoid to open said third valve to permit the engine to evacuate the second chamber whereby the auxiliary valve is opened by the differential in pressure on its opposite sides, thereby permitting the chamber in which the first-named valve reciprocates to be evacuated and permit the first-named valve to be opened by the differential in pressure on its opposite sides.

10. The combination with the intake manifold of an internal combustion engine, an accelerator for the engine, an ignition system for the engine, an air-intake conduit for supplying air directly to the manifold, a hollow piston valve in said conduit which when closed shuts off direct air supply to the manifold, a chamber in which said valve is reciprocable, said valve being mounted to project far enough from said chamber in its closed position so that its outer surface is exposed to atmospheric pressure, said valve having a port therein, an auxiliary hollow piston valve normally closing said port, a chamber in which the auxiliary valve reciprocates, said auxiliary valve having a port therein, a valve for closing the last-named port, a solenoid for opening said valve, means operable upon movement of the accelerator toward idling position and upon reduction of the speed of the engine to a predetermined point to energize said solenoid to open said third valve to permit the engine to evacuate the second chamber whereby the auxiliary valve may be opened by the differential in pressure on its opposite sides, thereby permitting the engine to evacuate the first chamber, whereby the firstnamed valve is opened, said ignition system being so connected electrically to said solenoid as to break the circuit to the solenoid when the engine speed falls to a still further predetermined point above idling speed.

l1. The combination with the intake manifold of an internal combustion engine, an accelerator for the engine, an air intake conduit for supplying air directly to the manifold, and a valve for normally closing said conduit to shut off direct air supply to the manifold, of electrically operated means for controlling the position of said valve, comprising a switch operable upon movement of the accelerator toward idling position and a second vacuum-operated switch mounted on the intake manifold and operable when the vacuum created by the engine in its operation reaches a predetermined point.

12. The combination with the intake manifold of an internal combustion engine, an ac'- celerator for the engine, an ignition system for the engine, an air-intake conduit for supplying air directly to the manifold, and a valveV for normally closing said conduit to shut off direct air supply to the manifold, of electrically operated means for controlling the position of said valve, means for closing a circuit to said electrically operated means comprising a switch operable upon movement of the accelerator toward idling position, and a vacuum-operated switch mounted on the intake manifold and operable when the vacuum created by the engine in its operation reaches a predetermined point, said ignition system being wired into said circuit to break the circuit when the engine speed is reduced to a predetermined point above its idling speed.

13. The combination with the intake manifold of an internal combustion engine, an accelerator for the engine, and the ignition system of the engine, of a valve for admitting air to the engine, and means for operating said valvey actuated by movement of the accelerator toward idling position from any operation position and by the vacuum created when the engine is' not delivering power, and the frequency of the impulses of current in the ignition system falls to a predetermind point.

14. The combination with the intake manifold of an internal combustion engine, an accelerator for the engine, an air-intake conduit for supplying air directly to the manifold, and a hollow piston-valve for normally closing said conduit to shut 0E direct air supply to the manifold, of a chamber in which the valve is reciprocable, said chamber being closed at one end and having its other end closed by said valve, a casing within which the chamber is mounted, said casing having air inlet openings through which air may be admitted into the casing, said valve having a port therein, an auxiliary piston valve for closing said port, a chamber in which said auxiliary valve is reciprocable, said chamber being contained within said iirst piston valve, said auxiliary valve having a port therein, a solenoidoperated valve reciprocable in the second chamber and adapted to close the port of the auxiliary valve, a solenoid for opening the solenoid operated valve, and means operable on movement of the accelerator toward idling position and on creation of a predetermined vacuum in the intake manifold when the engine is not delivering ypower for energizing said solenoid.

15. The combination with the intake manifold of an internal combustion engine, an accelerator for the engine, an air-intake conduit for supplying air directly to the manifold, the ignition system for the engine, and a hollow piston-valve for normally closing said conduit to shut off direct air supply to the manifold, of a chamber in which the valve is reciprocable, said chamber being closed at one end and having its other end closed by said valve, a casing within which the chamber is mounted, an air filter mounted within said casing between the chamber and the casing, said casing having air inlet openings through which air may be admitted through said filter into the casing, said valve having a port therein, an auxiliary piston valve for closing said port, a chamber in which said auxiliary valve is reciprocable, said chamber being contained within said first piston valve said auxiliary valve having a port therein, a solenoid-operated valve reciprocable in the second chamber and adapted to close the port of auxiliary valve, a solenoid for opening the solenoid operated valve, and means operable on movement of the accelerator toward idling position and on creation of a predetermined vacuum in the intake manifold when the engine is not delivering power for energizing said solenoid, and means operable when the frequency of the impulses in the ignition system falls below a predetermined value to break the circuit to said solenoid.

16. The combination with the intake manifold of an internal combustion engine, a carburetor for the engine, and an accelerator for the engine, of an adapter mounted between the carburetor and the intake manifold and communicating with both, means for admitting air into the adapter, a valve for closing off communication between said means and the adapter, and means operable on movement of the accelerator toward idling position and on creation of a predetermined vacuum in the intake manifold when the engine is not delivering power for opening said valve.

17. The combination with the intake manifold of an internal combustion engine, an ignition system for the engine, an air inlet conduit for admitting air to the manifold, a valve in said conduit for controlling admission of air to the manifold, electrically operated means for operating said valve, means including a relay for actuating said electrically operated means, and a vacuum operated switch for shunting the relay into the ignition circuit whereby the circuit to said relay and to said electrically operated means is maintained until the frequency of the impulses in said circuit falls below a predetermined limit, said vacuum-operated switch being actuated when a predetermined vacuum is created in the intake manifold while the engine is not delivering power.

18. The combination with the intake manifold of an internal combustion engine, a carburetor for the engine, and an ignition system for the engine comprising a primary coil, a secondary coil and a breaker controlling the primary coil, of an air inlet conduit for admitting air to the manifold in by-pass of the carburetor, a valve for controlling said inlet, means for opening said valve, and means operable while said valve is open to provide a constant current supply to the primary coil of the ignition system.

19. The combination with the intake manifold of an internal combustion engine, a carburetor for the engine, and an ignition system for the engine comprising a primary coil, a secondary coil, and a breaker controlling the primary coil, of an air inlet conduit for admitting air to the manifold in by-pass of the carburetor, a valve for controlling said inlet, means for opening said valve automatically when the engine is caused to absorb power, and means operable while said valve is open to provide a constant current supply to the primary coil of the ignition system.

20. The combination with the intake manifold of an internal combustion engine, a carburetor for the engine, an ignition system for the engine comprising a primary coil, a secondary coil, and a breaker controlling the primary coil, an accelerator, an air intake conduit for supplying air directly to the manifold in by-pass of the carburetor, and a valve in said conduit which when closed shuts oif the air supply, of electromagnetic means for assisting engine vacuum to open said valve, and means. for actuating said electromagnetic means comprising two switches controlled by the accelerator and by vacuum in the engine, respectively, and means also controlled by said switches for providing a constant current supply to the primary coil of the ignition system while said valve is open.

GEORGE J. TABER.

REFERENCES CITED The following references are of record in the le of this patent:

UNITED STATES PATENTS Number Name Date 1,970,002 Ericsson Aug. 14, 1934 1,998,494 Doering Apr. 23, 1935 2,018,426 Taber Oct. 22, 1935 2,035,775 Vander Veer Mar. 31 1936 

